Fat blends with crystal modifiers

ABSTRACT

Blends containing a vegetable fat or a blend of vegetable fats and a t least 0.1 wt % of a composition comprising ursolic acid and oleanolic acid in a weight ratio of 1:99 to 99:1 display a number of benefits such as high crystallisation rates. This modification of the crystallisation rate can be used to achieve a number of beneficial effects in the final fat blend or in the final food product containing the blend.

[0001] Fats per se or in the form of fat blends often suffer from problems during crystallisation. E.g. the crystallisation rate often is low or the crystal form of the fats results into products that are not sufficiently hard or are difficult to filter.

[0002] In order to cope with this problem the prior art discloses to add crystal modifiers to the fats, such as polymers or hardened fat components. The polymers however are not food grade and thus have to be removed from the food product which is not always easy and, if possible at all, complicates the processing, adding to the costs and making the use thereof economically unattractive. Hardened fats are not always healthy because of their high content of saturated fatty acid and have a negative impact on the viscosity and mouthfeel of the products.

[0003] Moreover crystal modifiers that are effective and that simultaneously add health benefits to the food products have not been disclosed yet in the prior art.

[0004] Therefore we studied whether we could find crystal modifiers that are effective for improving the crystallisation and the hardness of the product resulting therefrom and that simultaneously will add health benefits to the final food product. This study resulted in the finding that by adding a blend of ursolic acid and oleanolic acid to a fat per se or to a fat in a food product the crystallisation rate of the fat could be increased while simultaneously the hardness of the fat composition could be increased. Further it was found that the addition of the ursolic acid/oleanolic acid mixture also improved other properties of the total composition, such as oral mouthfeel; heat resistance; aeration properties and drying times (when applied in ice-cream coatings).

[0005] The known health effects of ursolic acid and oleanolic acid remain in the fat composition and / or the food product made thereof.

[0006] Health effects of ursolic acid and oleanolic acid can be found in eg JP 09/040689; JP 09.067249; CN 1085748; JP 1039973; JP 03287531; JP 03287530; EP 774255; JP 07258098; JP 07048260; JP 01132531; FR 2535203 and JP 1207262.

[0007] Therefore our invention concerns in the first instance a blend of a vegetable fat and/or a blend of vegetable fats and at least 0.1 wt %, preferably 0.1 to 10 wt %, most preferably 0.2 to 5 wt % of a natural health composition, wherein the natural health composition comprises a mixture of ursolic acid and oleanolic acid in a weight ratio of 1:99 to 99:1, preferably 10:90 to 90:10, more preferably 75:25 to 25:75.

[0008] It was found that very beneficial fat compositions could be obtained if the fat in above blend displays a solid fat content measured on a non-stabilised fat by NMR-pulse at the temperature indicated of: 5 to 90 at 5° C.; 2 to 80 at 20° C. and less than 15 at 35° C.

[0009] Non-stabilised being defined as a fat that has been subjected to the following temperature profile before measuring the fat content by NMR pulse: melt at 80° C. and cool to 0° C. and keep at 0° C. for 30 min, than warm up to measurement temperature and keep at that T for 30 min before measuring the N value. Very useful blends were obtained by making a blend comprising components A, B and C, wherein

[0010] A=a natural health composition, comprising a mixture of ursolic acid and oleanolic acid in a weight ratio of 1:99 to 99:1

[0011] B=a solid fat with a solid fat content at 20° C. of at least 20, measured on the unstabilised fat by NMR-pulse, preferably at least 45, most preferably at least 60 and

[0012] C=a fat with a content of fatty acids with 18 C-atoms with one to three double bonds of at least 40%,

[0013] which components A, B and C are present in amounts of:

[0014] at least 0.1 wt % A, preferably 0.1 to 20 wt %, most preferably 0.2 to 10 wt %

[0015] 8 to 90 wt % of B, preferably 25 to 75 wt %, most preferably 40 to 70 wt % and

[0016] 0 to 85 wt % of C, preferably 15 to 65 wt %, most preferably 20 to 50 wt %.

[0017] Although fats B and C could be selected from a wide range of fats we prefer to use fats B that are selected from the group consisting of palm oil, palm oil fractions, cocoa butter, cocoa butter equivalents, palm kernel oil, fractions of palm kernel oil, hardened vegetable oils such as hardened palm oil, hardened fractions of palm oil, hardened soybean oil, hardened sunflower oil, hardened rape seed oil, hardened fractions of soy, rape or sunflower oil, mixtures of one or more of these oils and interesterified mixtures thereof.

[0018] Fats C that are most preferred are fats selected from the group consisting of sunflower oil, high oleic sunflower oil, olive oil, soybean oil, rape seed oil, palm oil olein, olein fractions from other vegetable oils, high oleic vegetable oils and cotton seed oil.

[0019] The natural health composition can contain ursolic acid and oleanolic acid as the only components (eg by mixing of these components isolated from natural sources) however we found that we could obtain better health effects without effecting the physical effects of the blend of ursolic acid and oleanolic acid in a negative sense if the health component also comprises isoflavonoids and/or flavonoids in particular in amounts corresponding with 0.005 to 5 % of the total amount of ursolic acid and oleanolic acid.

[0020] Compositions containing the health components can be obtained from natural sources such as fruit skins, in particular skins of apples, pears, cranberries, cherries or prunes. All-spice oil is another natural source for ursolic acid/oleanolic acid mixtures. The health component can be obtained by extraction with a suitable organic solvent such as acetone.

[0021] Part of our invention are also food products having a fat phase in it and wherein the fat phase comprises at least partly the blends according to the invention. Examples of preferred food products are spreads (low fat or full fat), dressings, mayonnaises, cheese, creams, ice creams, ice cream coatings, confectionery coatings, fillings, sauces and culinary products.

[0022] Above food products preferably comprise 10 to 90 wt %, preferably 20 to 60 wt % of a continuous fat phase. The physical effects we describe above are the most pronounced in these products.

[0023] The modification in crystallisation behavior also results in a number of other effects that are also beneficial. Therefore our invention, according to another embodiment also comprises the use of a blend of ursolic acid and oleanolic acid in a fat blend per se or in a fat blend of a food product wherein the blend of ursolic acid and oleanolic acid is used to modify the crystallisation behavior of a fat blend or a fat blend in a final food product to

[0024] (i) increase the hardness of the fat blend or final product and/or

[0025] (ii) to improve the plasticity of the fat blend or final product and/or

[0026] (iii) to improve oral mouthfeel of the fat blend or final product and/or

[0027] (iv) to improve the heat resistance of the fat blend or final product and/or

[0028] (v) to increase the speed of crystallisation of the fat blend or final product and/or

[0029] (vi) to increase the aeration properties of the fat blend or final product and/or

[0030] (vii) to decrease drying times of ice-cream coatings.

[0031] According to a last embodiment our invention also concerns a process to make a blend with the composition according to the invention, wherein

[0032] (i) skins of a fruit such as apples, cherries, prunes, cranberries and pears are extracted with an organic solvent such as acetone

[0033] (ii) an extract of a mixture of ursolic acid and oleanolic acid is isolated and after removal of the solvent a mixture containing ursolic acid and oleanolic acid is obtained this mixture of acids obtained in (ii) is blended with a fat in the ratios required to obtain the compositions according to the invention.

EXAMPLES

[0034] 1. Three blends were made with the composition as given below: FAT HARDNESS CRYSTALL RATE COMPOSITION ADDITIVE AT 20° C. AT 15° C. 1.SF/hardstock no 55.5  8% after 10 min 87/13 2*.SF/hardstock ursolic acid/ 81 11% after 10 min 87/13 oleanolic acid ratio 60/40 2% 3.SF/hardstock fully hardened 73 11% after 10 min 87/13 palm oil 2%

[0035] The fat was melted at 60° C. and the additive was added and distributed homogeneously in the fat. Then the blend was stabilised for 15 min at 60° C. and cooled in a waterbath of 40° C. for 5 min. The mix was warmed to 15° C. and the solid fat content in the blend was measured with a time interval of 3 min for 30 min at 15° C. This led to the amounts of crystals formed which is an indication for the crystallisation rates as mentioned in above table.

[0036] The hardness of the fat obtained was measured at 20° C. using a standard Stevens equipment applying a penetration depth of 2 mm and a penetration speed of 0.5 mm per sec.

[0037] The fats (2) were found to have better hardness, better texture, better plasticity and processability than the fats (1) or (3) without the ursolic acid component.

[0038] 2. Effects of ursolic acid extract in an ice cream coating

[0039] Experimental

[0040] The recipe for the ice cream coatings was the following:

[0041] 475 g dark Callebaut 811

[0042] 25 g Fat

[0043] Two different fats were used:

[0044] A 25 g CCB (reference)

[0045] B 10 g ursolic acid extract/ 15 g CCB

[0046] The following characteristics were determined by coating small magnum ice creams.

[0047] Dripping temperature (°C.)

[0048] Dripping time (s)

[0049] Drying time (s)

[0050] Coating weight as % of total weight

[0051] Flexibility

[0052] Result & discussion TABLE 1 Summary of results Characteristic Sample A Sample B Dipping 40 40 temperature (° C.) Dripping time (s) 17 15 Drying time (s) 93 84 Coating weight (%) 40.7 45.3 Flexibility¹ −/+ ++

[0053] Observations:

[0054] The coatings A leaked ice cream through small holes in the coating.

[0055] Conclusion

[0056] Coating B have a shorter dripping time than coating A. Although the coating weight is higher (and thus coating is thicker) for coating B, the drying time is shorter than for coating A. The coating with the ursolic acid extract showed the least contraction after drying.

[0057] 3. Processing of Margarine

[0058] Three margarines were produced under the same process conditions.

[0059] a) Formulation Aqueous Phase Water 18.48% Potassium Sorbate 0.15 Citric Acid 0.07 SMP 1.0 Fat Phase Fat Blend 80.0 Hymono 8903 0.3 Fat Phase Product 1. 12% INES*, 88% SF (Control) Product 2. 12% INES*, 2% BO65, 86% SF Product 3. 12% INES*, 2% ursolic acid extract, 86% SF

[0060] b) Process Conditions

[0061] The process line was configured as:

[0062] Premix-Pump-A₁-unit-C₁-unit-A₂-unit

[0063] Premix temperature was set at 60° C. and 60-rpm stirrer speed. All units were set to 15° C., with shaft speeds set to 1000 rpm. Throughput was 50 g/min. using the constant displacement pump.

[0064] For all products a coarse premix was prepared by slowly adding the prepared aqueous phase to the oil phase in the premix tank. A 2 kg-batch size was employed Silverson mixing was applied for mixing of the powder into the fat phase prior to premix formation.

[0065] The mix was allowed to stir for 15 minutes before pumping was commenced. After pumping was started, the line was allowed to run for 15 minutes before any collection of product.

[0066] The following process parameters were noted: A₁ exit C₁ exit A₂ exit Line Pressure Product (° C.) (° C.) (° C.) (bar) Control 20.2 19.4 17.6 1.0 2% BO65 21.1 20.1 17.8 2.0 2% Ursolic 21.3 20.2 17.7 2.2 Acid extract

[0067] Three tubs of each product were collected.

[0068] All tubs were placed at 5° C. After one day, one tub of each was transferred to each of 5°, 10° and 15° for evaluations after one week.

[0069] c) Product Assessment

[0070] All samples spread easily with no apparent water loss. Stevens hardness (C-value) was measured and conductivity measurements were performed. The findings are summarized below: C-Value Conductivity Sample (g/cm²) (μScm⁻¹) 5° C. Storage Control 630 <10⁻⁵ 2% BO65 710 <10⁻⁵ 2% Ursolic Acid Extract 960 <10⁻⁵ 10° C. Storage Control 410 <10⁻⁵ 2% BO65 520 <10⁻⁵ 2% Ursolic Acid 560 <10⁻⁵ 15° C. Storage Control 340 <10⁻⁵ 2% BO65 500 <10⁻⁵ 2% Ursolic Acid 550 <10⁻⁵

[0071] Melting of the standard, 2% B065 and 2% Ursolic Acid extract spreads was observed under microscope fitted with a temperature controlled stage. This indicated that the standard and 2% Ursolic Acid extract spreads melting in the same general temperature region (36° to 38° C.). The B065 containing sample melted in the region of 43° to 45° C. That is, the Ursolic acid extract sample was not raised in melting point (and hence waxiness), but a large difference in hardness was noted compared to the standard. This is in contrast to the B065 equivalent that was harder than standard, but at the cost of increased melting point (i.e. waxiness.).

[0072] 4. Influence of ursolic acid in chocolate Reference 475 g dark Callebaut + 25 g CCB M1  10 g PO60 in 25 g CCB added to 465 g dark Callebaut M2  10 g Ursolic acid extract in 25 g CCB added to 465 g dark Callebaut

[0073] PO-60 is hardend palm oil with m.pt 60° C.

[0074] Mixtures were tempered in a Leatherhead temper kettle at 30° C. using 0.1% chocolate as seeding crystals. The viscosity was measured at temper and bars were made. Results Ref M1 M2 Tau0 30° C. 8.7 Pa 10.7 Pa 10.1 Pa Eta 30° C. 1.2 Pas  4.7 Pas  2.0 Pas Demoulding time 8 min  6 min  8 min Gloss 3/4  3  3/4

[0075] Heat resistance

[0076] Samples (solid chocolate bonbon) are stored during 15 hours at 40° C.

[0077] Dimension at 20° C.: 3.3×2.5 cm Height 1.9 cm

[0078] Dimension at 40° C.: Ref 4.0 × 4.3 cm Height 0.8-1.0 cm M1 4.0 × 3.8 cm Height 1.0-1.2 cm M2 3.3 × 3.0 cm Height 1.5-1.7 cm

[0079] The highest heat resistance was observed with ursolic acid extract containing sample.

[0080] Hardness

[0081] The settings on the Stevens Texture Analyzer were:

[0082] Distance: 2 mm

[0083] Speed: 0.5 mm/sec. Ref M1 M2 Temperature 20° C. 1 day 195 188 201 1 week 195 184 206 1 month 200 186 219 2 months 198 188 232 2 months 203 184 224 Temperature 25° C. 1 day 129 130 144 1 week 167 165 164 1 month 158 168 174 Temperature 30° C. 1 day  58  65  60 1 week  53  62  61 1 month 146 127 165

[0084] The chocolate with ursolic acid extract were found to have better hardness at all temperatures between 1 to 3 month of storage.

[0085] 5. Effects of ursolic acid extract on aeration properties

[0086] Experimental

[0087] The coatings were aerated for 20 minutes by using the Hobart N-50.

[0088] The samples were measured for density and hardness.

[0089] Coating A: 475 gram Callebaut 811±10 gram P060+15 gram CCB

[0090] Coating B: 475 gram Callebaut 811±10 gram Ursolic acid+15 gram CCB

[0091] Results

[0092] Density measurement:

[0093] The coating was weighed in a metal cup with a known volume of 90 cm³. A summary of the data is given in the table below. The density can than be calculated with the formula: ${Density} = \frac{{mass}({gram})}{{volume}\left( {cm}^{3} \right)}$

[0094] Hardness measurement:

[0095] The aerated coating was kept at 20° C. for 2 days before measurement. The settings on the Stevens Texture Analyzer were:

[0096] Distance: 2 mm

[0097] Speed: 0.5 mm/sec.

[0098] A summary of the hardness (load in grams) is given in the table as well.

[0099] Results Coating A Coating B Units Mass before aerating 111.5 110.3 gram Density before aerating 1.24 1.23 g/cm³ Mass after aerating 106.1 105 gram Density after aerating 1.18 1.17 g/cm³ Air 4.8 4.8 % Hardness 188 199 gram

[0100] Conclusion

[0101] In both coatings the same amount of air was determined after aeration whereas the hardness of the aerated coating with ursolic acid extract was found to be higher. 

1. Blend of a vegetable fat and/or a blend of vegetable fats and at least 0.1 wt %, preferably 0.1 to 10 wt %, most preferably 0.2 to 5 wt % of a natural health composition, wherein the natural health composition comprises a mixture of ursolic acid and oleanolic acid in a weight ratio of 1:99 to 99:1, preferably 10:90 to 90:10, more preferably 75:25 to 25:75.
 2. Blend according to claim 1 wherein the fat displays a solid fat content measured on a non-stabilised fat by NMR-pulse at the temperature indicated of: 5 to 90 at 5° C.; 2 to 80 at 20° C. and less than 15 at 35° C.
 3. Blend according to claim 1 wherein the blend comprises components A, B and C, wherein A=a natural health composition comprising a mixture of ursolic acid and oleanolic acid in a weight ratio of 1:99 to 99:1 B=a solid fat with a solid fat content at 20° C. of at least 20, measured on the unstabilised fat by NMR-pulse, preferably at least 45, most preferably at least 60 and C=a fat with a content of fatty acids with 18 C-atoms with one to three double bonds of at least 40%, which components a, b and c are present in amounts of: at least 0.1 wt % A, preferably 0.1 to 20 wt %, most preferably 0.2 to 10 wt % 8 to 90 wt % of B, preferably 25 to 75 wt %, most preferably 40 to 70 wt % and 0 to 85 wt % of C, preferably 15 to 65 wt %, most preferably 20 to 50 wt %.
 4. Blend according to claim 3 wherein fat B is selected from the group consisting of palm oil, palm oil fractions, cocoa butter, cocoa butter equivalents, palm kernel oil, fractions of palm kernel oil, hardened vegetable oils such as hardened palm oil, hardened fractions of palm oil, hardened soybean oil, hardened sunflower oil, hardened rape seed oil, hardened fractions of soy, rape or sunflower oil, mixtures of one or more of these oils and interesterified mixtures thereof.
 5. Blend according to claim 3 wherein fat C is selected from the group consisting of sunflower oil, high oleic sunflower oil, olive oil, soybean oil, rape seed oil, palm oil olein, olein fractions from vegetable oils, high oleic vegetable oils and cotton seed oil.
 6. Blend according to claim 1 wherein the natural health composition also comprises isoflavonoids and/or flavonoids in amounts corresponding with 0.005 to 5% of the total amount of ursolic acid and oleanolic acid.
 7. Blend according to claim 1 , wherein the natural health composition is obtained from fruit skins, in particular from the skins of apples, pears, cranberries, cherries or prunes.
 8. Food products with a fat phase wherein the fat phase comprises at least partly the blend according to any of claims 1 to 7 .
 9. Food products according to claim 8 , wherein the food product is selected from the group consisting of spreads (low fat or full fat), dressings, mayonnaises, cheese, creams, ice creams, ice cream coatings, confectionery coatings, fillings, sauces and culinary products
 10. Food products according to claim 9 , wherein the food product comprises 10 to 90 wt %, preferably 20 to 60 wt % of a continuous fat phase.
 11. Method to modify the crystallisation behavior of a fat blend or a fat blend in a final food product to (i) increase the hardness of the fat blend or final product and/or (ii) to improve the plasticity of the fat blend or final product and/or (iii) to improve oral mouthfeel of the fat blend or final product and/or (iv) to improve the heat resistance of the fat blend or final product and/or (v) to increase the speed of crystallisation of the fat blend or final product and/or (vi) to increase the aeration properties of the fat blend or final product and/or (vii) to decrease drying times of ice-cream coatings, by incorporating an effective amount of a blend of ursolic acid and oleanolic acid in the fat blend per se or in a fat blend of a food product
 12. Process to make a blend with the composition according to any of 1 to 7 claims, wherein (i) skins of a fruit such as apples, cherries, prunes and pears are extracted with an organic solvent such as acetone (ii) an extract of a mixture of ursolic acid and oleanolic acid is isolated and after removal of the solvent a mixture containing ursolic acid and oleanolic acid is obtained (iii) this mixture of acids obtained in (ii) is blended with a fat in the ratios required to obtain the compositions according to claims 1 to 7 . 